Emulation Aerosol Sucker

ABSTRACT

An emulation aerosol sucker includes a battery assembly, an atomizer assembly and a cigarette bottle assembly. An external thread electrode is located in one end of battery assembly. An internal thread electrode is located in one end of atomizer assembly. Said battery assembly and said atomizer assembly are connected by the screwthread electrode. Said cigarette bottle assembly is inserted into the other end of said atomizer assembly and both form one cigarette type or cigar type body.

TECHNICAL FIELD

This present invention relates to an electronic sucker unit, in particular, an emulation aerosol sucker that doesn't contain tar but nicotine.

BACKGROUND ART

Today when “smoking is harmful to your health” has become a common sense, there are one billion people smoking cigarettes, and this figure is still rising. On Mar. 1, 2003, the World Health Organization (WHO) issued the first international smoking ban—Framework Convention on Tobacco Control. According to WHO's data, smoking causes 4,900,000 deaths each year. Smoking causes serious respiratory system diseases and cancers, though it is a hard job to persuade the smokers to completely quit smoking.

Nicotine is the effective ingredient of cigarette, which produces a lot of tar mist as the cigarette burns. The tar mist accesses the pulmonary alveolus and is quickly absorbed into the blood. Nicotine thus acts on the receptor of the central nervous system, bringing the euphoria like stimulant drugs to the smokers, who feel light in the head and on wings as well.

Nicotine is a micromolecular alkaloid, which is basically harmless to human bodies with a small dosage. Plus, its half life period is extremely short in blood. Tar is the major harmful substance in tobacco. Tobacco tar comprises of several thousands of ingredients, dozens of which are carcinogenic substances. It has now been proved that second hand smoking is even more harmful to those who don't smoke.

To seek the cigarette substitutes that don't contain harmful tar but nicotine, many inventors have used the relatively pure nicotine to create such products as “Cigarette Patch”, “Nicotine Gargle”, “Aerosol Packed in the High Pressure Tank with Propellant”, “Nicotine Chewing Gum”, and “Nicotine Beverage”. These products are not as harmful as tar, but are absorbed very slowly. As a result, its peak concentration can't be effectively established in blood, and the smokers can't be satisfied to the full. In addition, the smokers are deprived of the “smoking” habit. Therefore, the substituting products are not real cigarette substitutes or products helping to quit smoking.

Contents of Invention

The purpose of this invention is to provide an emulation aerosol sucker that substitutes for cigarettes and helps the smokers to quit smoking. For this invention, the aerosol may be regarded as liquid drips suspended in the air.

The technical solution of this invention is the further innovation of the utility model called “Aerosol Electronic Cigarette” for which the inventor filed with the State Intellectual Property Office of the People's Republic of China on Apr. 14, 2000, with the application number of 20040031182.0, and the international application number of PCT/CN2005/000337.

The purpose of this invention is fulfilled with the following solution: this invention includes a battery assembly, an atomizer assembly and a cigarette bottle assembly. The battery assembly connects with one end of the atomizer assembly, and the cigarette bottle assembly is inserted into the other end of the atomizer assembly, thus forming one cigarette type or cigar type body.

Therein, an external thread electrode is located in one end of the battery assembly, and an internal thread electrode is located in one end of the atomizer assembly. The battery assembly and atomizer assembly are connected through the screwthread electrode. The battery assembly includes the indicator, battery, MOSFTET electric circuit board, sensor, silica gel corrugated membrane, primary screwthread electrode, primary negative pressure cavity, and primary shell. On one end of the primary shell is an external thread electrode, while on the other end is an indicator, where there is an indicator cap on one side, in which there is a fine hole. On the other side, the battery and MOSFET electric circuit board are connected successively. The sensor is located on MOSFET electric circuit board. Between the primary screwthread electrode and sensor is a silica gel corrugated membrane, on which there is the primary negative pressure cavity. The sensor is connected with the silica gel corrugated membrane through the switch spring. MCU is added between MOSFET electric circuit board and sensor. On the surface of the primary shell, there is a screen. The said MCU scans the sensor in the power-saving mode of pulse, and according to the signal parameters of the sensor, restricts the atomizing capacity with the integral function of frequency to single operation time. Also, the MCU accomplishes the pulse width modulation and over discharging protection for the constant power output, automatic cleansing for thousands of times per operation, step lighting/dying down control of the indicator, display of the operation times and battery capacity, automatic recovery after sensor malfunction shutdown, etc. The said sensor may be switch sensor made of elastic alloy slice, Hall element of linear output, semiconductor force-sensitive chip, semiconductor matrix thermoelectric bridge chip, capacitance or inductance sensor. The said indicators include two red LEDs. The said silica gel corrugated membrane may be made of fluorinated rubber, butyronitrile rubber, or elastic alloy film. The said external thread electrode is a gold-coated stainless steel or brass part with a hole drilled in the center. The said battery is a lithium ion battery, which may be either a rechargeable polymer lithium ion battery or a rechargeable lithium ion battery. The said atomizer assembly includes the internal thread electrode, air-liquid separator, atomizer and the secondary shell. One end of the secondary shell is inserted into the cigarette bottle assembly for connection, while the other end has an internal thread electrode, in which there is the secondary negative pressure cavity. The air-liquid separator and the atomizer are connected with the internal thread electrode successively. On the secondary shell, there is an air intake hole. The said internal thread electrode is a gold-coated stainless steel or brass part with a hole drilled in the center. The said air-liquid separator is made of stainless steel or plastic with a hole drilled. The said atomizer may be capillary impregnation atomizer or spray atomizer, inside which there is a heating body. The said spray atomizer has a spray hole on it. The said spray hole is made of foamed ceramics, micro-porous ceramics, foamed metal, stainless steel fiber felt, or chemical fiber molding, which are drilled for holes. The said heating body is made of the micro-porous ceramics on which nickel-chromium alloy wire, iron-chromium alloy wire, platinum wire, or other electrothermal materials are wound. Alternatively, it may be a porous component made of electrically conductive ceramics or PTC ceramics and associated with a sintered electrode. The surface of the heating body is sintered into high-temperature glaze to fix the zeolite grains, which are made of natural zeolite, artificial non-organic micro-porous ceramics or aluminum oxide grains. The said cigarette bottle assembly includes the cigarette liquid bottle, fiber and suction nozzle. The fiber containing cigarette liquid is located on one end of the cigarette liquid bottle, and this end is inserted into the secondary shell and lies against the atomizer. The suction nozzle is located on the other end of the cigarette liquid bottle. Between the fiber and interior wall of the cigarette liquid bottle is an air intake hole. The said cigarette liquid bottle and suction nozzle are made of non-toxic plastic. The said fiber is made of polypropylene or nylon. The cigarette liquid in the said fiber for atomization contains 0.1-3.5% nicotine, 0.05-5% tobacco flavor, 0.1-3% organic acid, 0.1-0.5% stabilizer, and propanediol for the remaining. The said sucker and its connecting structure may be loaded with conventional drugs for delivery to the lung.

This invention will bring the following benefits and active effects: For this invention, smoking doesn't bring any cigarette tar, considerably reducing the carcinogenic risks. At the same time, the smokers can still enjoy the feel and excitement of smoking, and there is no fire hazard since there is no need for igniting. In addition, the unit and its connecting structure of this invention may also be loaded with conventional drugs for delivery to the lung.

DESCRIPTION OF DRAWINGS

FIG. 1 is the visual appearance of the cigarette type of this invention.

FIG. 2A is the diagram of one structure of the battery assembly of this invention.

FIG. 2B is the diagram of another structure of the battery assembly of this invention.

FIG. 3 is the diagram of the diagram of the atomizer assembly of this invention.

FIG. 4 is the diagram of the cigarette bottle assembly of this invention.

FIG. 5A is the diagram of one internal structure of this invention.

FIG. 5B is the diagram of another internal structure of this invention.

FIG. 6 is the diagram of the structure of the charger of this invention.

FIG. 7 is the electric circuit diagram of MCU and MOSFET of this invention.

FIG. 8 is the diagram of the structure of the capillary impregnation atomizer of this invention.

FIG. 9 is the left view of FIG. 8.

FIG. 10 is the diagram of the structure of the spray atomizer of this invention.

FIG. 11 is the left view of FIG. 10.

FIG. 12 is the diagram of the structure of the cigar type of this invention.

SPECIFIC MODE FOR CARRYING OUT THE INVENTION

This invention is further described as follows on the basis of the drawings.

Example 1

As shown in FIG. 1, the visual appearance of this invention is similar to a cigarette inserted into the cigarette holder, and includes a battery assembly, an atomizer assembly and a cigarette bottle assembly. An external thread electrode (209) is located in one end of the battery assembly, and an internal thread electrode (302) is located in one end of the atomizer assembly. The battery assembly and atomizer assembly are connected through the screwthread electrode into an emulation cigarette. The cigarette bottle assembly is inserted into the other end of atomizer assembly, to form one cigarette type emulation aerosol sucker.

As shown in FIG. 2A, the battery assembly includes the indicator (202), lithium ion battery (203), MOSFTET electric circuit board (205), sensor (207), silica gel corrugated membrane (208), primary screwthread electrode (209), primary negative pressure cavity (210), and primary shell (211). On one end of the primary shell (211) is an external thread electrode (209), while on the other end is an indicator (202), where there is an indicator cap (201) on one side, in which there is a fine hole (501). On the other side, the lithium ion battery (203) and MOSFET (Metallic Oxide Semiconductor Field Effect Tube) electric circuit board (205) are connected successively. The sensor (207) is located on MOSFET electric circuit board (205). Between the primary screwthread electrode (209) and sensor (207) is a silica gel corrugated membrane (208), on which there is the primary negative pressure cavity (210). The sensor (207) is connected with the silica gel corrugated membrane (208) through the switch spring (212).

Therein, the sensor (207) may be switch sensor made of elastic alloy slice, Hall element of linear output, semiconductor force-sensitive chip, semiconductor matrix thermoelectric bridge chip, capacitance or inductance sensor. The indicators (202) include two red LEDs. The lithium ion battery (203) may be either a rechargeable polymer lithium ion battery or a rechargeable lithium ion battery. The external thread electrode (209) is a gold-coated stainless steel or brass part with a hole drilled in the center. The silica gel corrugated membrane (208) may alternatively be made of fluorinated rubber, butyronitrile rubber, or elastic alloy film.

As shown in FIG. 3, the atomizer assembly includes the internal thread electrode (302), air-liquid separator (303), atomizer (307) and the secondary shell (306). One end of the secondary shell (306) is inserted into the cigarette bottle assembly for connection, while the other end has an internal thread electrode (302), in which there is the secondary negative pressure cavity (301). The air-liquid separator (303) and the atomizer (307) are connected with the internal thread electrode (302) successively. On the secondary shell (306), there is an air intake hole (502). The air-liquid separator (303) is made of stainless steel or plastic with a hole drilled. The internal thread electrode (302) is a gold-coated stainless steel or brass part with a hole drilled in the center.

The atomizer (307) may be a capillary impregnation atomizer as FIGS. 8 and 9 show, or a spray atomizer as FIGS. 10 and 11 show. For this embodiment, it is a spray atomizer.

As shown in FIG. 4, the cigarette bottle assembly includes the cigarette liquid bottle (401), fiber (402) and suction nozzle (403). The fiber (402) containing cigarette liquid is located on one end of the cigarette liquid bottle (401), and this end is inserted into the secondary shell (306) and lies against the atomizer (307). The suction nozzle (403) is located on the other end of the cigarette liquid bottle (401). Between the fiber (402) and interior wall of the cigarette liquid bottle (401) is an air intake hole (503).

As shown in FIG. 5A, the standby state of this invention has the fully charged battery assembly shown on FIG. 2A fastened onto the atomizer assembly shown on FIG. 3, which is then inserted into the cigarette bottle assembly shown on FIG. 4. When the user slightly sucks the suction nozzle (403), the negative pressure forms on the silica gel corrugated membrane (208) through the air intake hole (503) and the primary and secondary negative pressure cavities (210, 301), and the silica gel corrugated membrane (208), under the action of suction pressure difference, distorts to drive the switch spring (212) and sensor (207), thus invoking MOSFET electric circuit board (205). At this moment, the indicators (202) are lit gradually; the lithium ion battery (203) electrifies the heating body (305) inside the atomizer (307) through MOSFET electric circuit board (205) as well as the internal and external thread electrodes (302, 209), so that the heating body (305) inside the atomizer (307) produces heat. The fiber (402) inside the cigarette liquid bottle (401) contains cigarette liquid, which soaks the micro-porous ceramics (801) inside the atomizer through the fiber (402). The air enters through the air intake hole (502), passes through the run-through hole on the air-liquid separator (303), and helps to form air-liquid mixture in the spray nozzle (304) of the atomizer (307). The air-liquid mixture sprays onto the heating body (305), gets vaporized, and is quickly absorbed into the airflow and condensed into aerosol, which passes through the air intake hole (503) and suction nozzle (403) to form white mist type aerosol.

When suction stops, the switch spring (212) and sensor (207) are reset; the atomizer (307) stops working; the indicators (202) gradually die down. When the operation times reaches the pre-set value, the atomizer (307) provides a work delay of 5-20 seconds per time, so as to remove the micro-dirt accumulated on the heating body (305).

Besides the micro-porous ceramics, the liquid supply material of the atomizer (307) may also be foamed ceramics, micro-porous glass, foamed metal, stainless steel fiber felt, terylene fiber, nylon fiber, nitrile fiber, aramid fiber or hard porous plastics. The heating body (305) is made of the micro-porous ceramics on which nickel-chromium alloy wire, iron-chromium alloy wire, platinum wire, or other electrothermal materials are wound. Alternatively, it may be a porous component directly made of electrically conductive ceramics or PTC (Positive Temperature Coefficient) ceramics and associated with a sintered electrode. The surface of the heating body (305) is sintered into high-temperature glaze to fix the zeolite grains, which are made of natural zeolite, artificial non-organic micro-porous ceramics or aluminum oxide grains. The cigarette liquid bottle (401) and suction nozzle (403) in the cigarette bottle assembly are made of non-toxic plastic, and inside them is the fiber (402) made of polypropylene fiber or nylon fiber to absorb cigarette liquid. In the battery assembly, there is a fine hole (501) on the indicator cap (201) for balancing the pressure difference on both sides of the silica gel corrugated membrane (208).

The cigarette liquid contains 0.1-3.5% nicotine, 0.05-5% tobacco flavor, 0.1-3% organic acid, 0.1-0.5% stabilizer, and propanediol for the remaining.

The primary and secondary shell (211, 306) of this invention are made of stainless steel tube or copper alloy tube with baked-enamel coating of real cigarette color.

As shown in FIG. 12, this invention may have the diameter of the battery assembly increased in proportion, so that it is consistent with the diameter of the atomizer assembly. Its shell may be decorated with the leaf veins and sub-gloss brown-yellow baked-enamel coating, to create a cigar type emulation aerosol sucker.

For charging of the lithium ion battery (203) of this invention, the screwthread electrode (601) that matches the external thread electrode (209) on the battery assembly may be used as the charging interface.

Example 2

As shown in FIG. 2B, the differences of this example from example 1 are as follows: MCU (206) is added between MOSFET electric circuit board (205) and sensor (207). On the surface of the primary shell (211), there is a screen (204) for display of the power of the lithium ion battery (203) and the sucking times.

As shown in FIG. 5B, the standby state of this invention has the fully charged battery assembly shown on FIG. 2B fastened onto the atomizer assembly, which is then inserted into the cigarette bottle assembly shown on FIG. 4. When the user slightly sucks the suction nozzle (403), the negative pressure forms on the silica gel corrugated membrane (208) through the air intake hole (503) and the primary and secondary negative pressure cavities (210, 301), and the silica gel corrugated membrane (208), under the action of suction pressure difference, distorts to drive the switch spring (212) and sensor (207), thus invoking MCU (206) and MOSFET electric circuit board (205). At this moment, the indicators (202) are lit gradually; the lithium ion battery (203) electrifies the heating body (305) inside the atomizer (307) through MOSFET electric circuit board (205) as well as the internal and external thread electrodes (302, 209), so that the heating body (305) inside the atomizer (307) produces heat. The fiber (402) inside the cigarette liquid bottle (401) contains cigarette liquid, which soaks the micro-porous ceramics (801) inside the atomizer through the fiber (402). The air enters through the air intake hole (502), passes through the run-through hole on the air-liquid separator (303), and helps to form air-liquid mixture in the spray nozzle (304) of the atomizer (307). The air-liquid mixture sprays onto the heating body (305), gets vaporized, and is quickly absorbed into the airflow and condensed into aerosol, which passes through the air intake hole (503) and suction nozzle (403) to form white mist type aerosol.

As shown in FIG. 7, when the action of suction evokes the sensor, MCU (206) scans the sensor (207) in the power-saving mode of pulse, and according to the signal parameters of the sensor (207), restricts the atomizing capacity with the integral function of frequency to single operation time. Also, the MCU (206) accomplishes the pulse width modulation and over discharging protection for the constant power output, automatic cleansing for thousands of times per operation, step lighting/dying down control of the indicator, display of the operation times and battery capacity, automatic recovery after sensor malfunction shutdown, etc.

The unit and its connecting structure of this invention may also be loaded with drugs for delivery to the lung.

Above are just specifications of a concrete example and applied example t of this invention. This doesn't necessarily restrict the scope of protection of this invention. Any equivalent modification or decoration made on the basis of the design spirit of this invention shall fall into the scope of protection of this invention. 

1. An emulation aerosol sucker includes a battery assembly, an atomizer assembly and a cigarette bottle assembly; the said cigarette bottle assembly includes the cigarette liquid bottle; the said atomizer assembly includes an atomizer; the cigarette bottle assembly is inserted into one end of the atomizer assembly, thus forming one cigarette type or cigar type body.
 2. The emulation aerosol sucker of claim 1, wherein an external thread electrode is located in one end of the said battery assembly, and an internal thread electrode is located in one end of the atomizer assembly. The battery assembly and atomizer assembly are connected through the screwthread electrode.
 3. The emulation aerosol sucker of claim 1, wherein the said battery assembly includes the battery, MOSFTET electric circuit board, sensor, primary screwthread electrode, primary negative pressure cavity, and primary shell. On one end of the primary shell is an external thread electrode, while on the other end, the battery and MOSFET electric circuit board are connected successively. The sensor is located on MOSFET electric circuit board.
 4. The emulation aerosol sucker of claim 3, wherein the said battery assembly further includes the silica gel corrugated membrane. Between the primary screwthread electrode and sensor is a silica gel corrugated membrane, on which there is the primary negative pressure cavity. The sensor is connected with the silica gel corrugated membrane through the switch spring.
 5. The emulation aerosol sucker of claim 3, wherein the said battery assembly further includes the indicators; there is an indicator on the other end of the primary shell, with an indicator cap on one side, in which there is a fine hole; MCU is added between MOSFET electric circuit board and sensor; on the surface of the primary shell, there is a screen.
 6. The emulation aerosol sucker of claim 5, wherein the said MCU scans the sensor in the power-saving mode of pulse, and according to the signal parameters of the sensor, restricts the atomizing capacity with the integral function of frequency to single operation time. Also, the MCU accomplishes the pulse width modulation and over discharging protection for the constant power output, automatic cleansing for thousands of times per operation, step lighting/dying down control of the indicator, display of the operation times and battery capacity, automatic recovery after sensor malfunction shutdown, etc. The said indicators include two red LEDs.
 7. The emulation aerosol sucker of claim 3, wherein the said sensor may be switch sensor made of elastic alloy slice, Hall element of linear output, semiconductor force-sensitive chip, semiconductor matrix thermoelectric bridge chip, capacitance or inductance sensor.
 8. The emulation aerosol sucker of claim 4, wherein the said silica gel corrugated membrane may be made of fluorinated rubber, butyronitrile rubber, or elastic alloy film.
 9. The emulation aerosol sucker of claim 3, wherein the said external thread electrode is a gold-coated stainless steel or brass part with a hole drilled in the center. The said battery is a lithium ion battery, which may be either a rechargeable polymer lithium ion battery or a rechargeable lithium ion battery.
 10. The emulation aerosol sucker of claim 1, wherein the said atomizer assembly includes the internal thread electrode, atomizer and the secondary shell. One end of the secondary shell is inserted into the cigarette bottle assembly for connection, while the other end has an internal thread electrode, in which there is the secondary negative pressure cavity.
 11. The emulation aerosol sucker of claim 3, wherein the said atomizer assembly includes the internal thread electrode, atomizer and the secondary shell. One end of the secondary shell is inserted into the cigarette bottle assembly for connection, while the other end has an internal thread electrode, in which there is the secondary negative pressure cavity.
 12. The emulation aerosol sucker of claim 6, wherein the said atomizer assembly includes the internal thread electrode, atomizer and the secondary shell. One end of the secondary shell is inserted into the cigarette bottle assembly for connection, while the other end has an internal thread electrode, in which there is the secondary negative pressure cavity.
 13. The emulation aerosol sucker of claim 7, wherein the said atomizer assembly includes the internal thread electrode, atomizer and the secondary shell. One end of the secondary shell is inserted into the cigarette bottle assembly for connection, while the other end has an internal thread electrode, in which there is the secondary negative pressure cavity.
 14. The emulation aerosol sucker of claim 10, wherein the said atomizer assembly includes an air-liquid separator; the air-liquid separator and the atomizer are connected with the internal thread electrode successively; on the secondary shell, there is an air intake hole.
 15. The emulation aerosol sucker of claim 14, wherein the said internal thread electrode is a gold-coated stainless steel or brass part with a hole drilled in the center. The said air-liquid separator is made of stainless steel or plastic with a hole drilled.
 16. The emulation aerosol sucker of claim 10, wherein the said atomizer may be capillary impregnation atomizer or spray atomizer, inside which there is a heating body. The spray atomizer has a spray hole on it.
 17. The emulation aerosol sucker of claim 15, wherein the said atomizer may be capillary impregnation atomizer or spray atomizer, inside which there is a heating body. The spray atomizer has a spray hole on it.
 18. The emulation aerosol sucker of claim 16, wherein the said spray hole is made of foamed ceramics, micro-porous ceramics, foamed metal, stainless steel fiber felt, or chemical fiber molding, which are drilled for holes.
 19. The emulation aerosol sucker of claim 16, wherein the said heating body is made of the micro-porous ceramics on which nickel-chromium alloy wire, iron-chromium alloy wire, platinum wire; alternatively, it may be a porous component made of electrically conductive ceramics or PTC ceramics and associated with a sintered electrode. The surface of the heating body is sintered into high-temperature glaze to fix the zeolite grains, which are made of natural zeolite, artificial non-organic micro-porous ceramics or aluminum oxide grains.
 20. The emulation aerosol sucker of claim 3, wherein the said cigarette bottle assembly includes the cigarette liquid bottle, fiber and suction nozzle. The fiber containing cigarette liquid is located on one end of the cigarette liquid bottle, and this end is inserted into the secondary shell and lies against the atomizer. The suction nozzle is located on the other end of the cigarette liquid bottle. Between the fiber and interior wall of the cigarette liquid bottle is an air intake hole.
 21. The emulation aerosol sucker of claim 10, wherein the said cigarette bottle assembly includes the cigarette liquid bottle, fiber and suction nozzle. The fiber containing cigarette liquid is located on one end of the cigarette liquid bottle, and this end is inserted into the secondary shell and lies against the atomizer. The suction nozzle is located on the other end of the cigarette liquid bottle. Between the fiber and interior wall of the cigarette liquid bottle is an air intake hole.
 22. The emulation aerosol sucker of claim 21, wherein the said cigarette liquid bottle and suction nozzle are made of non-toxic plastic; the said fiber is made of polypropylene or nylon.
 23. The emulation aerosol sucker of claim 22, wherein the cigarette liquid in the said fiber for atomization contains 0.1-3.5% nicotine, 0.05-5% tobacco flavor, 0.1-3% organic acid, 0.1-0.5% stabilizer, and propanediol for the remaining.
 24. The emulation aerosol sucker of claim 11, wherein the said atomizer assembly includes an air-liquid separator; the air-liquid separator and the atomizer are connected with the internal thread electrode successively; on the secondary shell, there is an air intake hole.
 25. The emulation aerosol sucker of claim 12, wherein the said atomizer assembly includes an air-liquid separator; the air-liquid separator and the atomizer are connected with the internal thread electrode successively; on the secondary shell, there is an air intake hole.
 26. The emulation aerosol sucker of claim 13, wherein the said atomizer assembly includes an air-liquid separator; the air-liquid separator and the atomizer are connected with the internal thread electrode successively; on the secondary shell, there is an air intake hole.
 27. The emulation aerosol sucker of claim 11, wherein the said atomizer may be capillary impregnation atomizer or spray atomizer, inside which there is a heating body. The spray atomizer has a spray hole on it.
 28. The emulation aerosol sucker of claim 12, wherein the said atomizer may be capillary impregnation atomizer or spray atomizer, inside which there is a heating body. The spray atomizer has a spray hole on it.
 29. The emulation aerosol sucker of claim 13, wherein the said atomizer may be capillary impregnation atomizer or spray atomizer, inside which there is a heating body. The spray atomizer has a spray hole on it.
 30. The emulation aerosol sucker of claim 11, wherein the said cigarette bottle assembly includes the cigarette liquid bottle, fiber and suction nozzle. The fiber containing cigarette liquid is located on one end of the cigarette liquid bottle, and this end is inserted into the secondary shell and lies against the atomizer. The suction nozzle is located on the other end of the cigarette liquid bottle. Between the fiber and interior wall of the cigarette liquid bottle is an air intake hole.
 31. The emulation aerosol sucker of claim 12, wherein the said cigarette bottle assembly includes the cigarette liquid bottle, fiber and suction nozzle. The fiber containing cigarette liquid is located on one end of the cigarette liquid bottle, and this end is inserted into the secondary shell and lies against the atomizer. The suction nozzle is located on the other end of the cigarette liquid bottle. Between the fiber and interior wall of the cigarette liquid bottle is an air intake hole.
 32. The emulation aerosol sucker of claim 13, wherein the said cigarette bottle assembly includes the cigarette liquid bottle, fiber and suction nozzle. The fiber containing cigarette liquid is located on one end of the cigarette liquid bottle, and this end is inserted into the secondary shell and lies against the atomizer. The suction nozzle is located on the other end of the cigarette liquid bottle. Between the fiber and interior wall of the cigarette liquid bottle is an air intake hole. 